Title :
The Quantitative Safety Assessment for Safety-Critical Software
Author :
Yu, Yangyang ; Johnson, Barry W.
Author_Institution :
Dept. of Electr. & Comput. Eng., Virginia Univ., Charlottesville, VA
Abstract :
The software fault failure rate bound is discussed and generalized for different reliability growth models. The fault introduction during testing and the fault removal efficiency are modeled to relax the two common assumptions made in software reliability models. Three approaches are introduced for the fault content estimation, and thus they are applied to software coverage estimation. A three-state non-homogenous Markov model is constructed for software safety assessment. The two most important metrics for safety assessment, steady state safety and MTTUF, are estimated using the three-state Markov model. A case study is conducted to verify the theory proposed in the paper
Keywords :
Markov processes; formal verification; program testing; safety-critical software; software fault tolerance; software metrics; fault content estimation; fault removal efficiency; formal verification; safety-critical software; software coverage estimation; software metrics; software reliability; software safety assessment; software testing; steady state safety; three-state Markov model; Oxidation; Production systems; Protection; Software maintenance; Software reliability; Software safety; Software testing; State estimation; Steady-state; Timing;
Conference_Titel :
Software Engineering Workshop, 2005. 29th Annual IEEE/NASA
Conference_Location :
Greenbelt, MD
Print_ISBN :
0-7695-2306-4
DOI :
10.1109/SEW.2005.44
